A nuclear fusion reactor in China, dubbed the "artificial sun," has broken its own record to bring humanity one step closer to near-limitless clean energy.
While neat, this is not self-sustaining — it’s taking more energy to power it than you’re getting out of it. (You can build a fusion device on your garage if you’re so inclined, though obviously this is much neater than that!)
One viewpoint is that we’ll never get clean energy from these devices, not because they won’t work, but because you get a lot of neutrons out of these devices. And what do we do with neutrons? We either bash them into lead and heat stuff up (boring and not a lot of energy), or we use them to breed fissile material, which is a lot more energetically favorable. So basically, the economically sound thing to do is to use your fusion reactor to power your relatively conventional fission reactor. Which is still way better than fossil fuels IMHO, so that’s something.
Even if we crack fusion power today, I can’t see it being deployed cheaply enough and quickly enough to compete with solar/wind+batteries. By the time we could get production fusion plants up and ready to feed power into the grid, it’d be 2050 and nobody would be interested in buying electricity from it.
Even in a world already powered 100% by renewables, fusion is attractive for high energy applications. For a current example see training of LLMs. However there are Industries with immense power requirements like Aluminium smelting that could use fusion power as well.
So far humans have found applications for all energy they were able to produce.
Fusion would provide orders of magnitude more power than solar. There’s a limit on how much we can practically get from solar, fusion would allow us to exceed that.
‘Too much power’ has never been an issue, and will likely not be an issue ever with solar. There are multitudes of technologies, especially in industry, that are currently impractical because they would consume too much energy.
We can already massively increase generation to meet the needs of those industries whenever we want. They’re impractical due to the cost of meeting their energy requirements, not because it’s impossible.
Unless fusion power plants are going to be free to build or last forever, they have the same practical limit as every other type of generation - they have to be paid for. It isn’t clear that fusion would be a huge step forward in cost per megawatt-hour.
The main attraction of fusion is near limitless clean energy generation. The corollary of near limitless is that per unit price will be extremely low. The tech is inherently scalable to larger reactors, and that means if you’re going to be building a reactor anyway, it’s easy to combine it with nearby industrial development plans to take advantage of it.
I think if we figure out nuclear fusion there will be induced demand for energy, in applications that were previously infeasible: desalination via distillation instead of reverse osmosis, direct capture of CO2 from the atmosphere, large scale water transport, ice and snowmaking, indoor farming, synthesized organic compounds for things like carbon sequestration or fossil fuel replacement or even food, etc.
Geoengineering might not be feasible today, but if energy becomes really cheap we might see something different.
I’d even say that it would make it “easier” to generate elements that are rare on earth for aplication purposes.
The first example already sort of feasible is production (and storage) of Helium.
And if we master (in the far, far future) both fusion and fission, then we can make almost any element “with ease”.
Basically we would be able to do what the alchemist dreamed and be able to “turn stones to gold”.
But nowadays, one of our “new gold” are rare earth like Neodymium for making magnets
And there are other elements that are even rarer and would have massive applications only if they were little bit more abundant than they are now
Now, again, that would be only true in a far, far future if (and a big if) we can truly master both fusion and fission (what I actually want to mean is that my comment is basically an “hallucination” similar to those on r/futurology)
I would think that using fusion or fission for synthesizing elements is going to still be less efficient (among all resources, not just energy) than using the newfound abundant/cheap energy to extract those preexisting elements from mixtures that exist on Earth.
Take neodymium, your example. That’s pretty abundant in the Earth’s crust. It’s just that it’s energy intensive to extract it from the mineral formations that naturally occur. At that point it’s still probably much cheaper, energy wise, to separate a bunch of minerals into their constituent elements, rather than try to synthesize atoms through fusion and fission.
The specifics are a pipe dream but the general principle holds: if energy suddenly becomes more plentiful and cheaper by orders of magnitude, society will find a way to use that new plentiful resource in ways that we can scarcely imagine today. That’s always been true of new inventions, where much of the post-invention innovation comes in the form of finding new applications for a thing that has already been invented.
Long distance transmission creates enormous power wastage, and cities are rarely located in places ideal for large scale wind and solar. Fusion can help deliver power to urban centres, reducing the acreage needed for a solar farm.
There are also inland places in northern latitudes that benefit little from solar. Wind and fusion would be a great energy mix for those places.
moar energy! there will never not be an application for energy production. specifically fusion has the benefit of being highly dense large scale production. which makes it attractive on a number of levels.
Economical energy production, sure, not any energy production. There is a reason we no longer burn wood to heat public baths.
I realize the science marketing of fusion over the past 60 years has been ‘unlimited free energy’, but that isn’t quite accurate.
Fusion (well, at least protium/deuterium) would be ‘unlimited’ in the sense that the fuel needed is essentially inexhaustible. Tens of thousands of years of worldwide energy demand in the top few inches of the ocean.
However that ‘free’ part is the killer; fusion is very expensive per unit of energy output. For one, protium/deuterium fusion is incredibly ‘innefficient’, most of the energy is released as high-energy neutrons which generates radioactive waste, damages the containment vessel, and has a low conversion efficiency to electricity. More exotic forms of fusion ameliorate this downside to a degree, but require rarer fuels (hurting the ‘unlimited’ value proposition) and require more extreme conditions to sustain, further increasing the per-unit cost of energy.
Think of it this way, a fusion plant has an embodied cost of the energy required to make all the stuff that comprises the plant, let’s call that C. It also has an operating cost, in both human effort and energy input, let’s call that O. Lastly it has a lifetime, let’s call that L. Finally, it has an average energy output, let’s call that E.
For fusion to make economical sense, the following statement must be true:
(E-O)*L - C > 0.
In other words, it isn’t sufficient that the reaction returns more energy than it requires to sustainT, it must also return enough excess energy that it ‘pays’ for the humans to maintain the plant, maintanence for the plant, and the initial building of the plant (at a minimum). If the above statement exactly equals zero, then the plant doesn’t actually given any usable energy - it only pays for itself.
This is hardly the most sophisticated analysis, I encourage you to look more into the economics of fusion if you are interested, but it gets to the heart of the matter. Fusion can be free, unlimited, and economically worthless all at the same time.
oh boy another economics dweeb who thinks they know what theyre on about. those were a lot of words for a false premise. There is no doubt that fusion can produce more energy than it costs to maintain. we have literal empirical examples of this occurring in nature. You forgetting a significant factor in your analysis: time.
The problem with fusion isnt the science behind its energy production. its the engineering behind the design of plants, unfortunately for fusion it suffers from being fairly unique in that its a high radiation, high heat domain which makes the engineering incredibly difficult to get funded and there isnt anything else comparable to piggy back off of. That’s currently your C value and those costs are one time. solar and wind also suffered from this for decades. fortunately those tech could piggy back off discovers in other domains.
The cost of fusion plants and the energy production they’ll eventually unlock will disappear soon as we figure out the containment issues, and we’re getting close. the reason you’re hearing about fusion more and more is because we had a break through in 2010 on superconductors allowing for stronger containment fields.
We’ve probably spent less than 500 billion globally on fusion research over the entire lifetime of the field. the ‘C’ value is actually remarkably low economically speaking for the return we’ll get.
I encourage you to seriously engage with the topic and not just read and regurgitate platitudes from popsci articles.
Solar and wind are nothing like fusion.
Educate yourself, but first maybe pause and spend a second to think that perhaps you aren’t the smartest person in the room and you shouldn’t begin a discussion by speaking down to someone.
When everything hard looks easy, it is a sign you don’t understand it as well as you think you do.
Oh child, you’re the one who walked into this conversation with a grade school take. Ive worked on software for these systems before i retired from the industry last year.
I never said solar and wind were anything like fusion beyond they’re all used to generate power and varying ranges of energy density per area. But I’m certainly better grounded than you in both the economics and ongoing challenges with fusion.
If you want people to take you seriously maybe don’t start the conversation with a grade school take on the situation and you wont be dismissed.
Helion has an interesting take on fusion reactors that generate power using electro magnetism and Copenhagen Atomics are trying to create Thorium reactors. I hope they will work better than the boiling they use in tocamac reactors
While neat, this is not self-sustaining — it’s taking more energy to power it than you’re getting out of it. (You can build a fusion device on your garage if you’re so inclined, though obviously this is much neater than that!)
One viewpoint is that we’ll never get clean energy from these devices, not because they won’t work, but because you get a lot of neutrons out of these devices. And what do we do with neutrons? We either bash them into lead and heat stuff up (boring and not a lot of energy), or we use them to breed fissile material, which is a lot more energetically favorable. So basically, the economically sound thing to do is to use your fusion reactor to power your relatively conventional fission reactor. Which is still way better than fossil fuels IMHO, so that’s something.
It seems like it’s probably too late.
Even if we crack fusion power today, I can’t see it being deployed cheaply enough and quickly enough to compete with solar/wind+batteries. By the time we could get production fusion plants up and ready to feed power into the grid, it’d be 2050 and nobody would be interested in buying electricity from it.
Even in a world already powered 100% by renewables, fusion is attractive for high energy applications. For a current example see training of LLMs. However there are Industries with immense power requirements like Aluminium smelting that could use fusion power as well.
So far humans have found applications for all energy they were able to produce.
Fusion would provide orders of magnitude more power than solar. There’s a limit on how much we can practically get from solar, fusion would allow us to exceed that.
Yeah, but there’s no prizes for producing way more power than we use. We’re not running out of space to put solar panels or batteries.
‘Too much power’ has never been an issue, and will likely not be an issue ever with solar. There are multitudes of technologies, especially in industry, that are currently impractical because they would consume too much energy.
We can already massively increase generation to meet the needs of those industries whenever we want. They’re impractical due to the cost of meeting their energy requirements, not because it’s impossible.
Unless fusion power plants are going to be free to build or last forever, they have the same practical limit as every other type of generation - they have to be paid for. It isn’t clear that fusion would be a huge step forward in cost per megawatt-hour.
The main attraction of fusion is near limitless clean energy generation. The corollary of near limitless is that per unit price will be extremely low. The tech is inherently scalable to larger reactors, and that means if you’re going to be building a reactor anyway, it’s easy to combine it with nearby industrial development plans to take advantage of it.
Bigger, more powerful fusion gear isn’t going to also be more expensive?
Lots of generation technologies scale, and costs fall as they do. That’s not something unique to fusion power.
What I would like fusion to do is power space ships
Why so you can spread the disease known as humanity and increased human suffering to near infinite levels?
Jk. Space would be fun.
I think if we figure out nuclear fusion there will be induced demand for energy, in applications that were previously infeasible: desalination via distillation instead of reverse osmosis, direct capture of CO2 from the atmosphere, large scale water transport, ice and snowmaking, indoor farming, synthesized organic compounds for things like carbon sequestration or fossil fuel replacement or even food, etc.
Geoengineering might not be feasible today, but if energy becomes really cheap we might see something different.
I’d even say that it would make it “easier” to generate elements that are rare on earth for aplication purposes.
The first example already sort of feasible is production (and storage) of Helium.
And if we master (in the far, far future) both fusion and fission, then we can make almost any element “with ease”.
Basically we would be able to do what the alchemist dreamed and be able to “turn stones to gold”.
But nowadays, one of our “new gold” are rare earth like Neodymium for making magnets
And there are other elements that are even rarer and would have massive applications only if they were little bit more abundant than they are now
Now, again, that would be only true in a far, far future if (and a big if) we can truly master both fusion and fission (what I actually want to mean is that my comment is basically an “hallucination” similar to those on r/futurology)
I would think that using fusion or fission for synthesizing elements is going to still be less efficient (among all resources, not just energy) than using the newfound abundant/cheap energy to extract those preexisting elements from mixtures that exist on Earth.
Take neodymium, your example. That’s pretty abundant in the Earth’s crust. It’s just that it’s energy intensive to extract it from the mineral formations that naturally occur. At that point it’s still probably much cheaper, energy wise, to separate a bunch of minerals into their constituent elements, rather than try to synthesize atoms through fusion and fission.
I kinda agree with you tho. It is way more realistically to have asteroid mining facilities before what I said in the previous comment
(And of course, earthly mining already exists and will get more efficient in the future anyways)
This seems like a pipe dream but I don’t disagree that it could open up some new applications
The specifics are a pipe dream but the general principle holds: if energy suddenly becomes more plentiful and cheaper by orders of magnitude, society will find a way to use that new plentiful resource in ways that we can scarcely imagine today. That’s always been true of new inventions, where much of the post-invention innovation comes in the form of finding new applications for a thing that has already been invented.
Indeed
Maybe for deep sea or space?
Long distance transmission creates enormous power wastage, and cities are rarely located in places ideal for large scale wind and solar. Fusion can help deliver power to urban centres, reducing the acreage needed for a solar farm.
There are also inland places in northern latitudes that benefit little from solar. Wind and fusion would be a great energy mix for those places.
Nah, it’d be quite useful for interstellar travel as but one example I’m helping with.
moar energy! there will never not be an application for energy production. specifically fusion has the benefit of being highly dense large scale production. which makes it attractive on a number of levels.
Economical energy production, sure, not any energy production. There is a reason we no longer burn wood to heat public baths.
I realize the science marketing of fusion over the past 60 years has been ‘unlimited free energy’, but that isn’t quite accurate.
Fusion (well, at least protium/deuterium) would be ‘unlimited’ in the sense that the fuel needed is essentially inexhaustible. Tens of thousands of years of worldwide energy demand in the top few inches of the ocean.
However that ‘free’ part is the killer; fusion is very expensive per unit of energy output. For one, protium/deuterium fusion is incredibly ‘innefficient’, most of the energy is released as high-energy neutrons which generates radioactive waste, damages the containment vessel, and has a low conversion efficiency to electricity. More exotic forms of fusion ameliorate this downside to a degree, but require rarer fuels (hurting the ‘unlimited’ value proposition) and require more extreme conditions to sustain, further increasing the per-unit cost of energy.
Think of it this way, a fusion plant has an embodied cost of the energy required to make all the stuff that comprises the plant, let’s call that C. It also has an operating cost, in both human effort and energy input, let’s call that O. Lastly it has a lifetime, let’s call that L. Finally, it has an average energy output, let’s call that E.
For fusion to make economical sense, the following statement must be true:
(E-O)*L - C > 0.
In other words, it isn’t sufficient that the reaction returns more energy than it requires to sustainT, it must also return enough excess energy that it ‘pays’ for the humans to maintain the plant, maintanence for the plant, and the initial building of the plant (at a minimum). If the above statement exactly equals zero, then the plant doesn’t actually given any usable energy - it only pays for itself.
This is hardly the most sophisticated analysis, I encourage you to look more into the economics of fusion if you are interested, but it gets to the heart of the matter. Fusion can be free, unlimited, and economically worthless all at the same time.
oh boy another economics dweeb who thinks they know what theyre on about. those were a lot of words for a false premise. There is no doubt that fusion can produce more energy than it costs to maintain. we have literal empirical examples of this occurring in nature. You forgetting a significant factor in your analysis: time.
The problem with fusion isnt the science behind its energy production. its the engineering behind the design of plants, unfortunately for fusion it suffers from being fairly unique in that its a high radiation, high heat domain which makes the engineering incredibly difficult to get funded and there isnt anything else comparable to piggy back off of. That’s currently your C value and those costs are one time. solar and wind also suffered from this for decades. fortunately those tech could piggy back off discovers in other domains.
The cost of fusion plants and the energy production they’ll eventually unlock will disappear soon as we figure out the containment issues, and we’re getting close. the reason you’re hearing about fusion more and more is because we had a break through in 2010 on superconductors allowing for stronger containment fields.
We’ve probably spent less than 500 billion globally on fusion research over the entire lifetime of the field. the ‘C’ value is actually remarkably low economically speaking for the return we’ll get.
I encourage you to seriously engage with the topic and not just read and regurgitate platitudes from popsci articles.
Solar and wind are nothing like fusion.
Educate yourself, but first maybe pause and spend a second to think that perhaps you aren’t the smartest person in the room and you shouldn’t begin a discussion by speaking down to someone.
When everything hard looks easy, it is a sign you don’t understand it as well as you think you do.
Just some advice for you as you grow up.
Oh child, you’re the one who walked into this conversation with a grade school take. Ive worked on software for these systems before i retired from the industry last year.
I never said solar and wind were anything like fusion beyond they’re all used to generate power and varying ranges of energy density per area. But I’m certainly better grounded than you in both the economics and ongoing challenges with fusion.
If you want people to take you seriously maybe don’t start the conversation with a grade school take on the situation and you wont be dismissed.
Helion has an interesting take on fusion reactors that generate power using electro magnetism and Copenhagen Atomics are trying to create Thorium reactors. I hope they will work better than the boiling they use in tocamac reactors